Ophthalmic laser apparatus, system, and method with high resolution imaging

ABSTRACT

System and method of photoaltering a region of an eye using a high resolution digital image of the eye. The system includes a laser assembly for outputting a pulsed laser beam, an imaging system for capturing a real-time high resolution digital image of the eye and displaying the digital image of the eye, a user interface receiving at least one laser parameter input, and a controller coupled to the laser assembly, imaging system, and user interface. The controller directs the laser assembly to output the pulsed laser beam to the region of the eye based on the laser parameter input.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional of, and claims priority to, U.S. patent application Ser. No. 12/416,355, filed on Apr. 1, 2009, which claims the benefit of U.S. Provisional Application No. 61/041,588, filed Apr. 1, 2008.

BACKGROUND OF THE INVENTION Field of the Invention

The field of the present invention is generally related to ophthalmic surgery systems and more particularly, to apparatus, systems, and methods of ophthalmic laser surgery with high resolution imaging.

Background

In current ophthalmic laser surgery procedures, a combination of optical microscopes and directed light from a light source is typically used to view the patient's eye. An optical microscope generally uses refractive lenses to focus light into the viewer's eye or another light detector. These refractive lenses and corresponding focusing mechanisms have been well-developed to date and are thus typically preferred to provide a magnified image of the eye. In many current ophthalmic laser systems, the optical microscope is positioned at a different location than the system interface providing operator control of the laser output. The physician performing the procedure will alternate between the system interface and the optical microscope to control and/or align the laser output with the eye. For example, the physician views the eye using the optical microscope to couple the laser system to the eye and views the eye using the system interface to align or centrate the laser output with eye. In so doing, the physician may be required to physically change position with respect to the ophthalmic laser system to view each of the optical microscope and system interface. Changing views generally increases the complexity of using such ophthalmic laser system.

More recently, image sensors, such as photoelectric light sensor arrays using charge coupled devices (CCDs) (e.g., complementary metal oxide semiconductor (CMOS) sensors), have been developed and capture digital images. When implemented as a digital camera, the digital camera can be used to capture images of the patient's eye. The images may be used to overlay a centration aid to assist the physician with alignment or centration of the laser output with the eye. However, while the images provided by these digital cameras may be sufficient for general observation of the eye, the resolution may not be sufficient for applanation, alignment or centration, and the like.

Accordingly, it is desirable to provide an ophthalmic surgical system and a method of ophthalmic laser surgery having an ergonomical view of the patient's eye throughout the ophthalmic procedure. It is also desirable to provide an ophthalmic surgical system and a method of ophthalmic laser surgery that displays a real-time, high resolution digital image of the patient's eye sufficient for performing any portion of the ophthalmic procedure. It is also desirable to provide a kit for an ophthalmic surgical system that replaces the optical microscope of the ophthalmic surgical system with a digital imaging system. Additionally, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description and the appended claims, taken in conjunction with the accompanying drawings and the foregoing technical field and background.

SUMMARY OF THE INVENTION

The present invention is directed towards photoaltering a region of an eye using a real-time, high resolution digital image of the eye. In one embodiment, a system is provided including a laser assembly configured to output a pulsed laser beam, an imaging system configured to capture a real-time high resolution digital image of the eye and display the real-time high resolution digital image of the eye, a user interface configured to receive at least one laser parameter input, and a controller coupled to the laser assembly, the imaging system, and the user interface. The controller is configured to direct the laser assembly to output the pulsed laser beam to the region of the eye based on the at least one laser parameter input.

In another embodiment, a system is provided including a laser assembly configured to output a pulsed laser beam, an imaging system, and a controller coupled to the laser assembly and the imaging system. The imaging system includes a digital camera, a first optical element configured to capture a first digital image of the eye with the digital camera, a second optical element configured to capture a second digital image of the eye with the digital camera, and a monitor configured to display a third digital image of the eye. The first digital image of the eye has a first resolution, and the second digital image of the eye has a second resolution. The third digital image of the eye is based on one of the first digital image of the eye and the second digital image of the eye. The controller is configured to produce the third digital image of the eye and direct the laser assembly to output the pulsed laser beam to the region of the eye in response to at least one operator input. The at least one operator input is based on the third digital image of the eye.

In another embodiment, a kit is provided for an ophthalmic laser system having an ocular microscope for viewing the eye. The kit includes an imaging system and a mounting apparatus. The imaging system includes an image sensor configured to capture a digital image of the eye, a monitor configured to display the digital image of the eye, an imaging interface, and a processor coupled to the image sensor, the display, and the interface. The mounting apparatus is configured to couple the imaging system to the ophthalmic laser system and thereby replace the ocular microscope.

In another embodiment, a method of photoaltering a region of an eye is provided including producing a real-time high resolution digital image of the eye, displaying the real-time high resolution digital image of the eye, and directing the pulsed laser beam at the region in response to an operator input. The operator input is based on the real-time high resolution digital image of the eye.

In another aspect, the imaging system is adjustable to accommodate a variety of operator characteristics (e.g., operator height, operator eyesight (e.g., corrected or uncorrected), and the like). For example, the monitor of the imaging system may be adjusted (e.g., lowered or raised, extended, retracted, tilted, and the like) for different operator heights and/or for presbyopic vision of the operator.

In another aspect, the imaging system has pre-determined magnification and/or focus depth settings for viewing the patient's eye. For example, the imaging system may have pre-determined settings for viewing a bubble layer (e.g., during or after photoalteration of the cornea), the iris, the corneal surface, and the like, as well has having a variety of pre-determined demagnification settings.

In another aspect, the imaging system has a graphical user interface providing touch-sensitive control (e.g., touch-controlled selections, touch-and-drag selections, and the like) for a variety of imaging system operations. For example, the graphical user interface may include buttons, icons, selectable text or images, or other operator-selectable representations of imaging system operations, such as magnification, video capture, file saving, and the like. A stylus, pen, or other device, which may or may not be sterile, may be used by the operator to indicate a selection on a touch-sensitive screen. The operator may also directly touch the touch-sensitive screen to indicate a selection.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, wherein like reference numerals refer to similar components:

FIG. 1 is a block diagram of a system for photoaltering a region of an eye in accordance with one embodiment of the present invention;

FIG. 2 is a block diagram of an ophthalmic laser system in accordance with one embodiment;

FIG. 3 is a block diagram of an interface system and the imaging system shown in FIGS. 1 and 2 in accordance with one embodiment of the present invention;

FIG. 4 is a front view of a graphical user interface in accordance with one embodiment; and

FIG. 5 is an exploded view of an ophthalmic laser system and an imaging system kit in accordance with one embodiment.

DETAILED DESCRIPTION

The present invention generally provides systems and methods for photoaltering (e.g., using a laser) a desired region of the eye (e.g., a sub-surface region of the eye, such as within the corneal epithelium and on or within Bowman's layer, the stroma, Descemet's membrane, the endothelium, or the like) with an enhanced imaging component. Examples of photoalteration include, but are not necessarily limited to, chemical and physical alterations, chemical and physical breakdown, disintegration, ablation, vaporization, or the like. Using a digital image of the eye, an operator aligns and/or centrates the laser with the desired region prior to directing pulsed laser beams to the desired region. At times, the operator may desire an enhanced image of the eye than provided in the initial digital image. In one embodiment, the system increases the contrast between the iris and pupil displayed in the digital image of the eye in response to an operator selected function. For example, a dark/light eye function may be provided to the operator on a display, as a separate component of the system, or otherwise available for selection by the operator via an input device. For darker colored eyes, the operator can select the dark/light eye function to increase the contrast between the iris and pupil displayed in the digital image and thereby improve the appearance of the digital image for alignment and/or centration (e.g., using a graphical aid overlaying the digital image) of the eye.

Referring to the drawings, a system 10 for photoaltering a desired region 12 of an eye is shown in FIG. 1. The system 10 is suitable for ophthalmic applications but may be used to photoalter a variety of materials (e.g., organic, inorganic, or a combination thereof). In one embodiment, the system 10 includes, but is not necessarily limited to, a laser 14 capable of generating a pulsed laser beam 18, an energy control module 16 for varying the pulse energy of the pulsed laser beam 18, a scanner 20, a controller 22, a user interface 32, an imaging system 34, and focusing optics 28 for directing the pulsed laser beam 18 from the laser 14 on the surface of or within the region 12 (e.g., sub-surface). The controller 22 communicates with the scanner 20 and/or focusing optics 28 to direct a focal point 30 of the pulsed laser beam onto or into the material 12. To impart at least a portion of this control, software (e.g., instrument software, and the like), firmware, or the like, can be used to command the actions and placement of the scanner 20 via a motion control system, such as a closed-loop proportional integral derivative (PID) control system. In this embodiment, the system 10 further includes a beam splitter 26 and a detector 24 coupled to the controller 22 to provide a feedback control mechanism for the pulsed laser beam 18. The beam splitter 26 and detector 24 may be omitted in other embodiments, for example, with different control mechanisms.

One example of photoalteration using pulsed laser beams is the photodisruption (e.g., via laser induced optical breakdown). Localized photodisruptions can be placed at or below the surface of the material to produce high-precision material processing. For example, a micro-optics scanning system may be used to scan the pulsed laser beam to produce an incision in the material, create a flap of material, create a pocket within the material, form removable structures of the material, and the like. The term “scan” or “scanning” refers to the movement of the focal point of the pulsed laser beam along a desired path or in a desired pattern.

To provide the pulsed laser beam, the laser 14 may utilize a chirped pulse laser amplification system, such as described in U.S. Pat. No. RE37,585, for photoalteration. U.S. Pat. Publication No. 2004/0243111 also describes other methods of photoalteration. Other devices or systems may be used to generate pulsed laser beams. For example, non-ultraviolet (UV), ultrashort pulsed laser technology can produce pulsed laser beams having pulse durations measured in femtoseconds. Some of the non-UV, ultrashort pulsed laser technology may be used in ophthalmic applications. For example, U.S. Pat. No. 5,993,438 discloses a device for performing ophthalmic surgical procedures to effect high-accuracy corrections of optical aberrations. U.S. Pat. No. 5,993,438 discloses an intrastromal photodisruption technique for reshaping the cornea using a non-UV, ultrashort (e.g., femtosecond pulse duration), pulsed laser beam that propagates through corneal tissue and is focused at a point below the surface of the cornea to photodisrupt stromal tissue at the focal point.

The system 10 is capable of generating the pulsed laser beam 18 with physical characteristics similar to those of the laser beams generated by a laser system disclosed in U.S. Pat. No. 4,764,930, U.S. Pat. No. 5,993,438, or the like. For example, the system 10 can produce a non-UV, ultrashort pulsed laser beam for use as an incising laser beam. This pulsed laser beam preferably has laser pulses with durations as long as a few nanoseconds or as short as a few femtoseconds. For intrastromal photodisruption of the tissue, the pulsed laser beam 18 has a wavelength that permits the pulsed laser beam 18 to pass through the cornea without absorption by the corneal tissue. The wavelength of the pulsed laser beam 18 is generally in the range of about 3 μm to about 1.9 nm, preferably between about 400 nm to about 3000 nm, and the irradiance of the pulsed laser beam 18 for accomplishing photodisruption of stromal tissues at the focal point is greater than the threshold for optical breakdown of the tissue. Although a non-UV, ultrashort pulsed laser beam is described in this embodiment, the laser 14 produces a laser beam with other pulse durations and different wavelengths in other embodiments. In one embodiment, the laser 14 preferably has a pulse repetition rate of about 150 kHz, and the cumulative amount of energy deposited into the cornea may be reduced while providing a comparable dissection quality (e.g., in comparison with photoalteration using slower pulse repetition rates) and while decreasing the overall time associated with the photoalteration procedure.

The focusing optics 28 direct the pulsed laser beam 18 toward the eye (e.g., onto the cornea) for plasma mediated (e.g., non-UV) photoablation of superficial tissue, or into the stroma for intrastromal photodisruption of tissue. The system 10 may also include an applanation lens (not shown) to flatten the cornea prior to scanning the pulsed laser beam 18 toward the eye. A curved, or non-planar, lens may substitute this applanation lens to contact the cornea in other embodiments.

The user interface 32 provides a flexible and simple environment for the operator to interact with the system 10. In one embodiment, the user interface 32 graphically displays (e.g., using a flat panel display or the like) information, such as from the instrument software controlling the operation of various components of the system 10, and provides a visual interface between the system 10 and the operator for inputting commands and data associated with the various components of the system. A graphical user interface (GUI) is preferably used with the user interface 32 employing menus, buttons, and other graphical representations that display a variety of selectable functions to be performed by the system 10 following selection. For example, the operator may point to an object and select the object by clicking on the object, touching a pre-designated region of a touch-screen displaying the GUI, or the like. Additional items may be presented on the GUI for operator selection, such as a button or menu item indicating an available sub-menu (e.g., a drop-down sub-menu). The user interface 32 may also utilize one or more of a variety of input devices including, but not necessarily limited to, a keyboard, a trackball, a mouse, a touch-pad, a touch-sensitive screen, a joystick, a variable focal length switch, a footswitch, and the like.

In addition to the user interface 32, the imaging system 34 displays a magnified real-time digital image of the patient's eye and provides an interface for viewing the patient's eye and operator control of the centration or alignment of the laser output with the patient's eye. In one embodiment, an alignment or centration aid is displayed by the imaging system 34 overlaying the digital image of the patient's eye. The aid corresponds with the position of laser output with reference to the patient's eye. As part of the photoalteration process, the output of the laser 14 is preferably aligned with the desired region 12 of the eye. For example, the output of the laser 14 may be substantially centered with reference to the pupil and iris of the patient's eye. Viewing the digital image displayed by the imaging system 34, the operator can center the aid based on the pupil and the iris of the patient's eye and thereby adjust the position of the laser output. To facilitate this alignment or centration process, the operator may desire a greater contrast between the iris and the pupil than shown in digital image of the patient's eye displayed by the imaging system 34.

In one embodiment, a user selectable dark/light eye function (e.g., represented as an icon, button, or the like) is provided (e.g., as a part of the imaging system 34, the user interface 32, or the system 10). When selected or activated (e.g., by touch), portions of the patient's eye that are normally darker in appearance in the digital image are displayed by the imaging system 34 with greater contrast (e.g., sufficient contrast to delineate each of the darker portions of the patient's eye. For example, for a brown iris and black pupil combination of a patient eye, the brown iris and black pupil are both relatively darker portions of the digitally imaged eye (e.g., in comparison with a lighter scleral portion of the digitally imaged eye). By selecting the dark/light eye function, the imaging system 34 displays a digital image of the patient's eye with greater contrast between the brown iris and the black pupil in the digital image, for example.

After alignment or centration, the system 10 directs the pulsed laser beam 18 to the desired region 12 of the eye. Movement of the focal point of the pulsed laser beam 18 is accomplished via the scanner 20 in response to the controller 22. The step rate at which the focal point is moved is referred to herein as the scan rate. For example, the scanner 20 can operate at scan rates between about 10 kHz and about 400 kHz, or at any other desired scan rate. In one embodiment, the scanner 20 generally moves the focal point of the pulsed laser beam 18 through the desired scan pattern at a substantially constant scan rate while maintaining a substantially constant separation between adjacent focal points of the pulsed laser beam 18. Further details of laser scanners are known in the art, such as described, for example, in U.S. Pat. No. 5,549,632, the entire disclosure of which is incorporated herein by reference.

In one embodiment, the scanner 20 utilizes a pair of scanning mirrors or other optics (not shown) to angularly deflect and scan the pulsed laser beam 18. For example, scanning mirrors driven by galvanometers may be employed where each of the mirrors scans the pulsed laser beam 18 along one of two orthogonal axes. A focusing objective (not shown), whether one lens or several lenses, images the pulsed laser beam 18 onto a focal plane of the system 10. The focal point 30 of the pulsed laser beam 18 may thus be scanned in two dimensions (e.g., the x-axis and the y-axis) within the focal plane of the system 10. Scanning along the third dimension, i.e., moving the focal plane along an optical axis (e.g., the z-axis), may be achieved by moving the focusing objective, or one or more lenses within the focusing objective, along the optical axis.

To create a flap, the pulsed laser beam 18 is typically scanned along in the desired region 12 using one or more patterns (e.g., a spiral pattern, a raster pattern, and the like) or combinations of patterns. When preparing a cornea for flap separation, for example, a circular area, oval area, or other shaped area may be scanned using a scan pattern driven by the scanning mirrors. The pulsed laser beam 18 photoalters the stromal tissue as the focal point 30 of the pulsed laser beam 18 is scanned along a corneal bed. The scan rates may be selected from a range between about 30 MHz and about 1 GHz with a pulse width in a range between about 300 picoseconds and about 10 femtoseconds, although other scan rates and pulse widths may be used.

The system 10 may additionally acquire detailed information about optical aberrations to be corrected, at least in part, using the system 10. Examples of such detailed information include, but are not necessarily limited to, the extent of the desired correction, and the location in the cornea of the eye associated with the correction (e.g., where the correction can be made most effectively). The refractive power of the cornea may be used to indicate corrections. Wavefront analysis techniques, made possible by devices such as a Hartmann-Shack type sensor (not shown), can be used to generate maps of corneal refractive power. Other wavefront analysis techniques and sensors may also be used. The maps of corneal refractive power, or similar refractive power information provided by other means, such as corneal topographs or the like, can then be used to identify and locate the optical aberrations of the cornea that require correction. The amount of photoalteration can be based on the refractive power map.

One example of an ophthalmic scanning application is a laser assisted in-situ keratomilieusis (LASIK) type procedure where a flap is cut from the cornea to establish extracorporeal access to the tissue that is to be photoaltered. The flap may be created using random scanning or one or more scan patterns. A sidecut is created around a desired perimeter of the flap such that the ends of the sidecut terminate, without intersection, to leave an uncut segment. This uncut segment serves as a hinge for the flap. The flap is separated from the underlying stromal tissue by scanning the laser focal point across a resection bed, the perimeter of which is approximately defined by the sidecut. In one embodiment, the perimeter of the resection bed is greater than the perimeter of the anterior surface of the flap to form a wedge-shaped flap edge. Once this access has been achieved, photoalteration is completed, and the residual fragments of the photoaltered tissue are removed from the cornea. In another embodiment, intrastromal tissue may be photoaltered by the system 10 so as to create an isolated lenticle of intrastromal tissue. The lenticle of tissue can then be removed from the cornea.

FIG. 2 is a block diagram of an ophthalmic laser system 40 in accordance with one embodiment of the present invention. Referring to FIGS. 1 and 2, the ophthalmic laser system 40 includes, but is not necessarily limited to, a laser source 42 providing a pulsed laser beam (e.g., the pulsed laser beam 18), a beam monitoring and processing module 44, a beam delivery module 46 coupled to the beam monitoring and processing module 44, the user interface 32, and the imaging system 34. The pulsed laser beam is supplied to the beam monitoring and processing module 44 where the pulse energy, the focal point separation, and optionally the minimum sub-surface depth of the pulsed laser beam are controlled. The beam delivery module 46 scans the pulsed laser beam along a desired scan region. In this embodiment, the ophthalmic laser system 40 can be coupled to an eye 31 via a patient interface 33, and the patient interface 33 may be coupled to the ophthalmic laser system 40 at a moveable loading deck 35, for example. The configuration of the ophthalmic laser system 40 may vary as well as the organization of the various components and/or sub-components of the ophthalmic laser system 40. For example, some components of the beam delivery module 46 may be incorporated with the beam monitoring and processing module 44 and vice versa.

The user interface 32 is coupled to the beam delivery module 45, and a variety of system parameters may be input or modified by the operator via the user interface 32 to control the beam properties and thus produce the desired photoalteration. For example, the user interface 32 may include a display presenting a graphical user interface with the various system parameters and an input device (not shown) for selecting or modifying one or more of these parameters. The number and type of system parameters vary for each type of ophthalmic procedure (e.g., flap creation, photorefractive keratectomy (PRK), LASIK, laser assisted sub-epithelium keratomileusis (LASEK), corneal pocket creation, corneal transplant, corneal implant, corneal onlay, and the like).

In one embodiment, the operating pulse energy and operating focal point separation of the pulsed laser beam may be input or selected by the operator via the user interface 48. For flap creation, the operator is prompted via the user interface 48 with a selection of flap pattern parameters (e.g., upper flap diameter, depth of incision in cornea, hinge angle, hinge position, and the like). The parameters may be displayed as default values for selective modification by the operator. Additional parameters may also be displayed by the user interface 48 for different procedures using the system 40. For example, a variety of pre-programmed ring pattern parameters (e.g., inner ring diameter, outer ring diameter, cornea thickness, incision axis, and the like) are provided for corneal ring implant procedures.

In response to the system parameters selected or input via the user interface 48, the beam monitoring and processing module 44 and/or the beam delivery module 46 produce a pulsed laser beam with the corresponding properties. In one embodiment, the beam monitoring and processing module 44 includes, but is not necessarily limited to, an energy attenuator 41, one or more energy monitors 43, and an active beam positioning mirror 45. The pulsed laser beam is directed from the laser source 42 to the energy attenuator 41, then to the energy monitor 43, and then to the active beam positioning mirror 45. The active beam positioning mirror 45 directs the pulsed laser beam from the beam monitoring and processing module 44 to the beam delivery module 46. Using the energy attenuator 41 and energy monitor 43, the pulse energy of the pulsed laser beam may be varied to desired values. Additionally, the spatial separation of the focal points of the pulsed laser beam may be varied by the beam monitoring and processing module 44.

The beam delivery module 46 scans the pulsed laser beam at the desired scan region (e.g., the region 12). In one embodiment, the beam delivery module 46 includes, but is not necessarily limited to, a beam position monitor 47, an x-y scanner 49, a beam expander 52, one or more beam splitters 54, and a z-scanning objective 56. The pulsed laser beam is received from the beam monitoring and processing module 44 by the x-y scanner 49 and directed to the beam expander 52, and the beam expander 52 directs the pulsed laser beam to the z-scanning objective via the beam splitter(s) 54. The z-scanning objective 56 can vary the focal point depth of the pulsed laser beam (e.g., from the anterior surface of the eye 31 or cornea to any depth within the eye 31 up to and including the retinal region).

Prior to initiating scanning or otherwise initiating photoalteration of the eye 31, the ophthalmic laser system 40 is coupled to the eye 31. In one embodiment, the patient interface 33 provides a surface for contacting the cornea of the patient's eye 31, which may also be used to applanate the cornea. A suction ring assembly 53 or other device may be applied to the eye 31 to fixate the eye prior to coupling the ophthalmic laser system 40 to the eye (e.g., via the patient interface 33). In one embodiment, the suction ring assembly 53 has an opening providing access to the eye 31 when coupled thereto. The imaging system 34 may be used to facilitate the coupling of the ophthalmic laser system 40 with the eye 31. For example, by providing a real-time image of the fixated eye, the operator can view the eye to properly center the output of the beam delivery module 46 over the desired region 12.

Once the ophthalmic laser system 40 is coupled to the eye 31, the imaging system 34 may be used for alignment or centration of the laser output (e.g., the beam delivery module 46 output) and/or applanation of the cornea using the patient interface 33. The imaging system 34 preferably provides a real-time, magnified, high resolution digital image of the eye 31 and includes, but is not necessarily limited to, an image sensor 57, an imaging interface 59, and an image processor 58 coupled to the sensor 57 and the interface 59. An image of the eye 31 is captured using the image sensor 57 and displayed by the imaging interface 59. In one embodiment, a high resolution digital camera (e.g., a high-definition digital video camera based on charge coupled devices (CCDs) or the like) is used to capture the image and display the image on the imaging interface 59.

Although FIG. 2 illustrates a combination of the image sensor 57 and beam splitters 54 for capturing the image, the image sensor 57 may be located in a variety of different positions or operate solely or operate with additional optical elements to directly or indirectly capture images of the eye 31. For example, the image sensor 57 may be located substantially adjacent to the z-scanning objective 56 to directly capture images of the eye 31. In one embodiment, the image sensor 57 is mounted on a moveable gantry to vary the image focal plane captured by the image sensor 57 and optically coupled with a variable aperture (not shown) (e.g., positioned between the image sensor 57 and the eye 31) for controlling the depth of focus and/or the amount of light sensed by the image sensor 57. In another embodiment, at least one or more of a focus control for varying the image focal plane captured by the image sensor 57 and a focus depth control are incorporated into the image sensor 57.

The imaging interface 59 includes, but is not necessarily limited to, an input device for operator selection of a variety of system parameters (e.g., associated with coupling the ophthalmic laser system 40 with the eye 31, image control, and the like) and a monitor displaying the real-time, magnified, high resolution digital image of the eye 31. The input device may include one or more of a keyboard, a trackball, a mouse, a touch-pad, a touch-sensitive screen, a joystick, a variable focal length switch, a footswitch, and the like. The monitor is preferably adjustable to accommodate a variety of operator characteristics (e.g., operator height, operator eyesight (e.g., corrected or uncorrected), and the like). For example, the monitor may be adjusted (e.g., lowered or raised, extended, retracted, tilted, pivoted, and the like) for different operator heights and/or to accommodate the vision of the operator.

In one preferred embodiment, the imaging interface 59 includes a touch-sensitive screen displaying a graphical user interface for selecting the system parameters and for viewing the alignment or centration of the laser output with reference to the desired region 12 of the eye 31 and/or viewing the applanation of the cornea. The graphical user interface provides a variety of buttons, icons, or the like corresponding with different functions for selection by the operator, and the operator may select a particular function by touching the corresponding button displayed on the touch-sensitive screen. Examples of the different functions that may be provided by the graphical user interface at the imaging interface 59 include, but are not necessarily limited to, a dark/light eye function, an increase magnification function, a decrease magnification function, an increase illumination function, a decrease illumination function, an increase focal depth function, a decrease focal depth function, the functions and system parameters provided by the user interface 32, as previously described, and the like.

Operator control of the beam delivery module 46 alignment with the eye 31, applanation of the cornea, and/or centration may be provided via the input device of the imaging interface 59 or via a separate input device (e.g., a joystick). For example, the operator may control the raising, lowering, or lateral movement (two-dimensions) of the loading deck 35 via the joystick while viewing the digital image of the eye 31 provided by the imaging system 34. The operator can adjust the lateral position (e.g., an x-axis position and a y-axis position) of the loading deck 35 to align the output of the beam delivery module 46 with the eye 31 and lower the loading deck 35 (e.g., along a z-axis) to guide the patient interface 33 into a pre-determined position with the suction ring 53 (e.g., coupling the beam delivery module 46 with the eye 31). An indicator may be displayed by the imaging interface 59 (e.g., a green light) when the beam delivery module 46 is properly coupled with the eye 31 and/or when an applanation surface of the patient interface 33 contacts the cornea. The operator may then applanate the cornea by further lowering the beam delivery module 46 (e.g., the loading deck 35 and patient interface 33) using the input device, while monitoring the degree of applanation as indicated by the digital image of the eye 31, and discontinuing movement of the beam delivery module 46 at a desired degree of applanation determined by viewing the digital image of the eye 31.

In one embodiment, a centration aid is displayed as an overlay on the digital image of the eye 31 for assisting in centering the laser output with the desired region 12 of the eye 31 (e.g., to be photoaltered). The centration aid corresponds with the current position of the laser output with reference to the eye 31 (e.g., the two-dimensional position in the focal plane of the pulsed laser beam and/or axial alignment of the pulsed laser beam with reference to an optical axis of the eye 31). The operator may align or center the laser output using the joystick or other input device. For example, by centering the centration aid with reference to the image of the pupil, the iris, or both the pupil and iris, displayed by the imaging interface 59, the operator may adjust the output of the beam delivery module 46 to be centered with reference to the pupil, the iris, or both the pupil and iris. The centration aid may also be configured with reference to other anatomical indicators of the eye or other reference points. Following alignment or centration, the operator may initiate scanning and photoalteration of the desired region 12 of the eye 31.

The operator may continuously view the digital image of the eye 31 provided by the imaging system 34 during alignment or centration, applanation, the entire process from initial fixation of the eye through photoalteration of the eye, or any other portion of such process. For example, the physician performing the ophthalmic laser procedure may perform the ophthalmic laser procedure from fixation of the eye 31 (e.g., using the suction ring assembly 53), through coupling of the beam delivery module 46 to the eye 31 (e.g., via coupling of the patient interface 33 with the suction ring assembly 53), through applanation of the cornea, through centration, and through photoalteration of the desired region 12 of the eye 31, while maintaining viewing of the digital image of the eye 31 provided by the imaging system 58. The physician does not have to switch from viewing the imaging interface 59 to viewing the user interface 32 and/or does not have to switch from viewing the imaging interface 59 to directly viewing the patient's eye. Using the imaging system 34 simplifies and enhances the physician's focus on the ophthalmic laser procedure by allowing the physician to view a single display for an entire ophthalmic laser procedure.

At times, the operator may desire a greater contrast between the pupil and the iris shown in the digital image of the eye 31 captured by the imaging system 34. In general, the image sensor 57 captures an initial digital image of the eye 31 based on default settings. For example, in one embodiment, the image sensor 57 has a gamma function, which controls the intensity or brightness of each pixel of the digital image displayed by the imaging interface 59 based on the image detected by the image sensor 57. The typical default is a linear gamma function, and the image detected by the image sensor 57 is displayed by the imaging system 34 on the imaging interface 59 as with an intensity or brightness based on the linear gamma function.

As previously mentioned, a user-selectable button is provided at the imaging interface 59 for activating the dark/light eye function. When this function is selected (e.g., by touching a dark/light eye button on the touch-sensitive screen), the image processor 58 modifies the gamma function to a pre-determined setting (e.g., different from the default) and alters the intensity or brightness of the displayed image to enhance contrast between the lower intensity or lower brightness levels. This setting may be selected such that darker-colors detected by the image sensor 57 (e.g., brown eyes and black pupils) that are relatively close in intensity or brightness levels can be contrasted from one another to a greater degree than provided using the linear gamma function. For example, the image processor 58 retrieves a first set of intensity or brightness values (associated with the default gamma function setting) from a look-up table (not shown), which is used to produce the initial digital image of the eye 31. When the dark/light eye function is selected, the image processor 58 retrieves a second set of intensity or brightness values (associated with a non-linear or greater than linear gamma function setting) from the look-up table, which is used to produce an enhanced digital image of the eye 31 with greater contrast between the pupil and iris, particularly suited for darker-colored eyes.

The darker-colors detected by the image sensor 57 are thus displayed by the imaging interface 59 with a greater difference in relative intensity or brightness. In effect, selecting the dark/light eye function modifies the setting of the gamma function from the default setting to a setting that is more sensitive to the changes in intensity or brightness for darker-colored regions of the eye 31 as detected by the image sensor 57. For example a small change in intensity or brightness from one darker-color to another darker-color detected by the image sensor 57 produces corresponding pixels with a greater change in intensity or brightness (e.g., greater than a linear change, such as two-fold increase, a three-fold increase, a squared function, an exponential function, and the like). The enhanced digital image of the eye 31 provided by the dark/light eye function further assists the operator during centration, or any other portion of the ophthalmic laser procedure, and is particularly suited for darker-colored eyes. De-selecting the dark/light eye function (e.g., by touching the dark/light eye button again) returns the gamma function setting to the default gamma function setting (e.g., linear).

In one embodiment, the image processor 58 is additionally coupled to the user interface 32 to transmit the captured digital image of the eye 31 to the user interface 32. In this embodiment, the digital image of the eye 31 may also be displayed by the user interface 32. Other functions, such as control of the various system parameters, may be transferred to the imaging system 34. Similarly, functions provided by the imaging system 34, such as alignment or centration, may also be transferred to the user interface 32.

In another embodiment, the imaging system 34 includes at least two different optical elements (not shown) that may be switched with one another to accommodate different frame rates (e.g., associated with different image sensors or digital cameras). These optical elements are interchanged along the optical image path to the image sensor 57. One advantage provided by the interchangeability of these optical elements is to maintain a substantially constant image processing.

FIG. 3 is a block diagram of an interface system 80 and the imaging system 34 shown in FIGS. 1 and 2 in accordance with one embodiment of the present invention. In this embodiment, the interface system 80 includes, but is not necessarily limited to, the user interface 32 having a touch-sensitive screen, a touch screen controller 84 coupled to the user interface 32, and a central computing unit 86 coupled to the user interface 32 and the touch screen controller 84. The central computing unit 86 includes, but is not necessarily limited to, one or more communication ports (e.g., USB ports), a network component 92 (e.g., an Ethernet Gbit local area network (LAN) board), a video component 90 (e.g., a video board) coupled to the user interface 82 via a video input port (e.g., a cathode ray tube (CRT) mode input port), and a central processing unit (CPU) 88 (e.g., a CPU mother board). The central computing unit 86 is also coupled to the user interface 32 via one of the communication ports and to the touch screen controller 84 via another of the communication ports. The video component 90 receives a video signal (e.g., a National Television System Committee (NTSC) video signal) via an input port (e.g., an NTSC port) from the imaging system 34. Thus, the user interface 82 may operate with the central computing unit 86 as a console and may operate to display digital video received from the imaging system 34.

The imaging system 34 includes, but is not necessarily limited to, the imaging interface 59 having a display 64, a touch screen controller 66 coupled to the imaging interface 59, a brightness controller 70 coupled to the display 64, a processor 68 (e.g., a single board computer (SBC) with embedded board expandable (EBX) format and using a Pentium M 1.8 GHz microprocessor produced by Intel Corp.) coupled to the brightness controller (e.g., via an inverter port) and the touch screen controller, a data storage device 72 (e.g., a hard drive or the like) coupled to the processor 68, and the image sensor 57 coupled to the processor 68. The image sensor 57 is preferably a digital camera having a high resolution (e.g., 1624×1224 resolution) and more preferably has a resolution of about 2 megapixels or greater with a high frame rate (e.g., 1624×1224 at about 20 frames per second or greater), such as the model GRAS-20S4M/C digital camera manufactured by Point Grey Research, Inc. The display 64 may have a resolution (e.g., 1024×768 resolution) that is less than the resolution of the digital camera. In these embodiments, the information captured by the high resolution digital camera is compressed by the processor 68 to the resolution of the display 64.

In this embodiment, the imaging interface 59 has a touch-sensitive screen and a graphical user interface is displayed on the display 64 by the processor 68. The processor 68 operates with the touch screen controller 66 and brightness controller 70 to control or modify the brightness level of the digital image of the eye when the dark/light eye button is selected. As previously described, the digital image of the eye captured by the image sensor 57 is displayed on the display 64 with an initial brightness level. For example, when the dark/light eye button is not selected, the processor 68 retrieves intensity or brightness data corresponding with the default setting from a look-up table stored in the data storage device 72.

The brightness level of the digital image may be modified when the dark/light eye button is selected. For example, the dark/light eye button may be displayed on the display 64 during operation of the graphical user interface by the processor 68. When the dark/light eye button is selected (e.g., detected by the touch screen controller 66), the touch screen controller 66 transmits a signal to the processor 68 indicating activation of the dark/light eye function. The processor 68 retrieves intensity or brightness data corresponding with the dark/light eye function from a look-up table stored in the data storage device 72 and instructs the brightness controller 70 to modify the digital image displayed on the display 64. In one embodiment, the dark/light eye function may have varying degrees of pre-determined contrast settings (e.g., corresponding with one or more of the different non-linear or greater than linear gamma functions), and the graphical user interface may be modified with a slide feature, successive button-tap feature, or the like, to provide operator selection of the different contrast settings.

The graphical user interface may also provide selectable buttons, icons, or the like for operator control of focus and/or magnification of the displayed digital image of the eye. A first stepper/controller 76 is coupled to the processor 68 to control the focus of the image sensor 57, and a second stepper/controller 78 is coupled to the processor 68 to control the aperature of the image sensor 57. By detection (e.g., via the touch screen controller 66) of a focus button (e.g., an increase focus button or a decrease focus button) selection or a magnification button (e.g., an increase magnification button or a decrease magnification button) selection, the processor 68 instructs the stepper/controller 76, 78, respectively.

In one embodiment, the data storage device 72 stores one or more applications (e.g., containing computer readable instructions) that when executed by the processor 68 cause the system 10, 40 to photoalter the desired region 12 of the eye 31. For example, the application, when executed, produces an initial digital image of the eye 31 having an initial contrast between the iris and the pupil, increases (e.g., from the initial contrast) the contrast between the iris and pupil upon operator selection of the dark/light eye function, displays a modified digital image of the eye 31 having the increased contrast the iris and pupil, centrates the eye 31 based on the increased contrast between the iris and pupil, and directs the pulsed laser beam at the desired region 12. When producing the initial digital image (e.g., without activation of the dark/light eye function), the processor 68 retrieves brightness data from the data storage device 72 that corresponds with a default setting (e.g., the default gamma function setting). To increase the contrast between the iris and pupil, the processor 68 retrieves brightness data from the data storage device 72 corresponding with a modified setting (e.g., the non-linear or greater than linear gamma function setting). The modified digital image is produced based on the brightness data corresponding with the modified setting.

The processor 68 is also coupled (e.g., with a LAN port) to the central computing unit 86 via a network, such as Ethernet and/or a GigaLAN, and information (e.g., selected system parameters, graphical user interface functions, and the like) may be transferred between the imaging system 34 and the interface system 80.

FIG. 4 is a front view of a graphical user interface 94 in accordance with one embodiment. The graphical user interface 94 may be used with the imaging system 34 and/or the user interface 32 shown in FIGS. 1-3 to display a real-time, high resolution, digital image 95 of the patient's eye and provide a touch-sensitive screen for operator input. The graphical user interface 94 includes, but is not necessarily limited to, a focus control 99, a magnification control 98, preset focus depth buttons 93 (e.g., Preset 1, Preset 2, and Preset 3), a dark/light eye button 97, and a window 87 displaying the digital image 95 of the patient's eye. For example, the preset focus depth buttons 93 may be set at pre-determined magnification and/or focus depth settings for viewing the patient's eye, such as for viewing a bubble layer (e.g., during or after photoalteration of the cornea), the iris, the corneal surface, and the like, as well has having a variety of pre-determined de-magnification settings. Additional buttons, icons, or the like may be provided by the graphical user interface 94.

In this embodiment, a centration aid 96 is also displayed in the window 87 as an overlay on the digital image 95 of the eye. Each of the focus and magnification controls 99 and 98, respectively, is a sliding button representation that may be controlled by operator touch and/or touch and slide (e.g., up or down). During centration, the operator can touch the dark/light eye button 97 to enhance or increase the contrast between the pupil 97 and the iris 85 in the digital image 95. This enhanced or increased contrast improves the operator's ability to delineate between the pupil 85 and the iris 91 for centering the centration aid 96 (e.g., aligning the centration aid 96 with an outer boundary 89 of the iris 85). The centration aid 96 may have a variety of different configurations.

The graphical user interface 94 may also provide buttons for video capture, file saving, and the like. Although the operator may indicate a selection on the graphical user interface 94 via direct contact on the touch-sensitive screen, a stylus, a pen, or other device, which may be sterile, may be used by the operator to indicate selections on the touch-sensitive screen. Each of the functions associated with the graphical user interface 94 are implemented via the image processor 58, such as previously described, in one embodiment. For example, the image processor 58 detects operator selections via the touch screen controller 66, stores images or video in the data storage device 72, controls the focus depth and magnification via the stepper/controller 76, 78, and alters the displayed digital image via the brightness controller 70.

FIG. 5 is an exploded view of an ophthalmic laser system 100 and an imaging system kit 110 in accordance with one embodiment. A user interface 102, a control knob 104, and a laser output head 106 are shown on an exterior 101 of the ophthalmic laser system 100. The control knob 104 can control the raising, lowering, or lateral movement (two-dimensions) of the laser output head 106. In a standard configuration, the ophthalmic laser system 100 includes an ocular microscope (not shown). In this embodiment, the ocular microscope has been removed along with a portion of the exterior 101 thereby providing an access 105 to various components contained within the ophthalmic laser system 100.

The imaging system kit 110 has an imaging interface 112 and a mounting assembly 114 for coupling the imaging system kit 110 to the ophthalmic laser system 110. In addition to the imaging interface 112, the imaging system kit 110 includes similar components as the imaging system 34 (FIG. 3), such as the image sensor 57, the image processor 68, the imaging interface 59, etc. For example, the imaging interface 112 is similar to the imaging interface 59 (FIG. 3), which has the display 64 (e.g., a tiltable, retractable, extendable, or otherwise moveable display). The mounting assembly 114 preferably couples the imaging system kit 110 to the ophthalmic laser system 110 about the access 105, and thus replaces the ocular microscope. In one embodiment, the mounting assembly 114 couples the user interface 102 with the imaging system kit 110 to display the digital image of the eye captured by the image sensor 57.

The imaging system kit 110 also includes a cover 116 to replace the portion of the exterior 101 of the ophthalmic laser system 100 removed along with the ocular microscope. When integrated with the ophthalmic laser system 110 (and thereby replacing the ocular microscope), the imaging system kit 110, provides a graphical user interface (e.g., the graphical user interface 94 shown in FIG. 4) and the various imaging system controls previously described with the imaging system 34. The operator can control the laser output head 106 via the control knob 104 while viewing the digital image of the eye provided by the imaging system kit 110.

Thus, systems 10, 40 of photoaltering a desired region of the eye are provided using a real-time high resolution digital image of the eye. Additionally, an imaging system kit 110 is provided for upgrading conventional ophthalmic laser systems (e.g., replacing exisiting ocular microscopes on the ophthalmic laser system with the imaging system). Examples of some refractive eye surgery applications for the systems 10, 40 and/or using the kit 110 include, but are not necessarily limited to, photorefractive keratectomy (PRK), LASIK, laser assisted sub-epithelium keratomileusis (LASEK), or the like. Using the imaging system 34 of the systems 10, 40 or the imaging system kit 110, the operator may perform a variety of ophthalmic laser surgical procedures without the use of conventional ocular microscope and while viewing and/or interfacing with a single display.

While embodiments of this invention have been shown and described, it will be apparent to those skilled in the art that many more modifications are possible without departing from the inventive concepts herein. 

1-12. (canceled)
 13. A system for photoaltering a region of an eye, the system comprising: a laser assembly configured to output a pulsed laser beam; an imaging system comprising: a digital camera; a first optical element configured to capture a first digital image of the eye with the digital camera, the first digital image of the eye having a first resolution; a second optical element configured to capture a second digital image of the eye with the digital camera, the second digital image of the eye having a second resolution; and a monitor configured to display a third digital image of the eye, the third digital image of the eye based on one of the first digital image of the eye and the second digital image of the eye; and a controller coupled to the laser assembly and the imaging system, the controller configured to: produce the third digital image of the eye; and direct the laser assembly to output the pulsed laser beam to the region of the eye in response to at least one operator input, the at least one operator input based on the third digital image of the eye.
 14. (canceled)
 15. The system of claim 13, wherein the laser assembly is configured to produce the pulsed laser beam with a pulse repetition rate of about 150 kHz.
 16. A kit for an ophthalmic laser system, the ophthalmic laser system comprising an ocular microscope configured to view an eye, the kit comprising: an imaging system comprising an image sensor configured to capture a digital image of the eye, a monitor configured to display the digital image of the eye, an imaging interface, and a processor coupled to the image sensor, the display, and the interface; and a mounting apparatus configured to couple the imaging system to the ophthalmic laser system and thereby replace the ocular microscope.
 17. A kit according to claim 16, wherein the ophthalmic laser system further comprises a user interface configured to display a plurality of laser operating parameters and further configured to display the digital image of the eye; and wherein the mounting apparatus is further configured to couple the imaging system to the user interface.
 18. A kit according to claim 16, wherein the image sensor is a digital camera having at least a 1624×1224 resolution and a frame rate of at least about 20 frames per second.
 19. A kit according to claim 16, wherein the monitor has at least a 1024×768 resolution.
 20. A kit according to claim 16, wherein the laser assembly is configured to produce the pulsed laser beam with a pulse repetition rate of about 150 kHz
 21. A kit according to claim 16, wherein the image sensor is further configured to capture a first digital image of the eye, wherein the monitor is further configured to display a second digital image of the eye, and wherein the controller is further configured to receive the first digital image of the eye and produce the second digital image of the eye via a compression of the first digital image of the eye.
 22. A kit according to claim 16, wherein the imaging system is further configured to receive at least one imaging parameter input, and wherein the controller is further configured to alter the digital image of the eye displayed by the imaging system in response to the at least one imaging parameter input.
 23. A kit according to claim 13, wherein the monitor is a moveable monitor.
 24. A kit according to claim 13, wherein the processor is further configured to display a graphical user interface on the monitor.
 25. A kit according to claim 24, wherein the graphical user interface comprises at least one button corresponding to a pre-determined focal setting, and wherein the processor is further configured to control a focal depth of the image sensor based on a selection of the at least one button.
 26. A kit according to claim 25, wherein the pre-determined focal setting is selected from a group consisting of a bubble layer focal setting, a corneal surface focal setting, an iris focal setting, and a pre-determined demagnification setting.
 27. A kit according to claim 24, wherein the graphical user interface comprises a button, wherein the processor is further configured to store a data file based on the digital image of the eye upon selection of the button.
 28. A kit according to claim 27, wherein the data file represents a video based on the digital image of the eye.
 29. A method of photoaltering a region of an eye using a pulsed laser beam, the method comprising the steps of: producing a real-time high resolution digital image of the eye; displaying the real-time high resolution digital image of the eye; and directing the pulsed laser beam at the region in response to an operator input, the operator input based on the real-time high resolution digital image of the eye.
 30. The method of claim 29, wherein the step of producing a real-time high resolution digital image of the eye comprises capturing the real-time high resolution digital image of the eye with a digital camera, the digital camera having at least a 1624×1224 resolution and a frame rate of at least about 20 frames per second.
 31. The method of claim 29, wherein the step of displaying the real-time high resolution digital image of the eye comprises displaying the real-time high resolution digital image of the eye on a monitor having at least a 1024×768 resolution. 